Integrated Seed Proteome and Phosphoproteome Analyses Reveal Interplay of Nutrient Dynamics,Carbon–Nitrogen Partitioning,and Oxidative Signaling in Chickpea

Nutrient dynamics in storage organs is a complex developmental process that requires coordinated interactions of environmental, biochemical, and genetic factors. Although sink organ developmental events have been identified, understanding of translational and post‐translational regulation of reserve synthesis, accumulation, and utilization in legumes is limited. To understand nutrient dynamics during embryonic and cotyledonary photoheterotrophic transition to mature and germinating autotrophic seeds, an integrated proteomics and phosphoproteomics study in six sequential seed developmental stages in chickpea is performed. MS/MS analyses identify 109 unique nutrient‐associated proteins (NAPs) involved in metabolism, storage and biogenesis, and protein turnover. Differences and similarities in 60 nutrient‐associated phosphoproteins (NAPPs) containing 93 phosphosites are compared with NAPs. Data reveal accumulation of carbon–nitrogen metabolic and photosynthetic proteoforms during seed filling. Furthermore, enrichment of storage proteoforms and protease inhibitors is associated with cell expansion and seed maturation. Finally, combined proteoforms network analysis identifies three significant modules, centered around malate dehydrogenase, HSP70, triose phosphate isomerase, and vicilin. Novel clues suggest that ubiquitin–proteasome pathway regulates nutrient reallocation. Second, increased abundance of NAPs/NAPPs related to oxidative and serine/threonine signaling indicates direct interface between redox sensing and signaling during seed development. Taken together, nutrient signals act as metabolic and differentiation determinant governing storage organ reprogramming.     

The Protein Phosphorylation Landscape of Mouse Spermatids during Spermiogenesis

The characteristic tadpole shape of sperm is formed from round spermatids via spermiogenesis, a process which results in dramatic morphological changes in the final stage of spermatogenesis in the testis. Protein phosphorylation, as one of the most important post‐translational modifications, can regulate spermiogenesis; however, the phosphorylation events taking place during this process have not been systematically analyzed. In order to better understand the role of phosphorylation in spermiogenesis, large‐scale phosphoproteome profiling is performed using IMAC and TiO₂ enrichment. In total, 13 835 phosphorylation sites, in 4196 phosphoproteins, are identified in purified mouse spermatids undergoing spermiogenesis in two biological replicates. Overall, 735 testis‐specific proteins are identified to be phosphorylated, and are expressed at high levels during spermiogenesis. Gene ontology analysis shows enrichment of the identified phosphoproteins in terms of histone modification, cilium organization, centrosome and the adherens junction. Further characterization of the kinase‐substrate phosphorylation network demonstrates enrichment of phosphorylation substrates related to the regulation of spermiogenesis. This global protein phosphorylation landscape of spermiogenesis shows wide phosphoregulation across a diverse range of processes during spermiogenesis and can help to further characterize the process of sperm generation. All MS data are available via ProteomeXchange with the identifier PXD011890.     

Advances,challenges and tools in characterizing bacterial serine,threonine and tyrosine kinases and phosphorylation target sites.

Introduction: The cellular response to infection by bacterial pathogens involves a complex and highly regulated series of pathways that carry messages to various parts of the cell. These messages are transferred using post-translational modifications including phosphorylation by kinases. Understanding the host’s signaling pathways is valuable in identifying potential treatment targets, but the bacterial signaling pathways and host-pathogen crosstalk are equally important to the development of therapeutics.

Areas covered: This review summarizes some of the recent findings related to the bacterial phosphoproteome and especially serine/threonine/tyrosine sites, including methods and considerations for identifying novel phosphosites. We also consider the bioinformatics tools that have been developed to sift through the large volume of data in these studies and connect them to biologically relevant knowledge about pathways and function. Literature databases used include PubMed and Google Scholar from April 2018 to December 2018.

Expert opinion: While the field has developed significantly in the past decade of research, high-quality experimental sequence data remains the limiting factor to future research into bacterial phosphoproteomics. As more proteomes are explored, it will be easier to tailor tools and techniques to prokaryotes. It will be necessary to consider the phosphoproteome in the broader biological context, through interdisciplinary collaborations.     

Large‐scale phosphorylation mapping reveals the extent of tyrosine phosphorylation in Arabidopsis

Protein phosphorylation regulates a wide range of cellular processes. Here, we report the proteome‐wide mapping of in vivo phosphorylation sites in Arabidopsis by using complementary phosphopeptide enrichment techniques coupled with high‐accuracy mass spectrometry. Using unfractionated whole cell lysates of Arabidopsis, we identified 2597 phosphopeptides with 2172 high‐confidence, unique phosphorylation sites from 1346 proteins. The distribution of phosphoserine, phosphothreonine, and phosphotyrosine sites was 85.0, 10.7, and 4.3%. Although typical tyrosine‐specific protein kinases are absent in Arabidopsis, the proportion of phosphotyrosines among the phospho‐residues in Arabidopsis is similar to that in humans, where over 90 tyrosine‐specific protein kinases have been identified. In addition, the tyrosine phosphoproteome shows features distinct from those of the serine and threonine phosphoproteomes. Taken together, we highlight the extent and contribution of tyrosine phosphorylation in plants.     

Deciphering Spatial Protein–Protein Interactions in Brain Using Proximity Labeling

Cellular biomolecular complexes including protein–protein, protein–RNA, and protein–DNA interactions regulate and execute most biological functions. In particular in brain, protein–protein interactions (PPIs) mediate or regulate virtually all nerve cell functions, such as neurotransmission, cell–cell communication, neurogenesis, synaptogenesis, and synaptic plasticity. Perturbations of PPIs in specific subsets of neurons and glia are thought to underly a majority of neurobiological disorders. Therefore, understanding biological functions at a cellular level requires a reasonably complete catalog of all physical interactions between proteins. An enzyme-catalyzed method to biotinylate proximal interacting proteins within 10 to 300 nm of each other is being increasingly used to characterize the spatiotemporal features of complex PPIs in brain. Thus, proximity labeling has emerged recently as a powerful tool to identify proteomes in distinct cell types in brain as well as proteomes and PPIs in structures difficult to isolate, such as the synaptic cleft, axonal projections, or astrocyte–neuron junctions. In this review, we summarize recent advances in proximity labeling methods and their application to neurobiology.     

Analysis of protein phosphorylation: methods and strategies for studying kinases and substrates

Protein phosphorylation is a highly conserved mechanism for regulating protein function, being found in all prokaryotes and eukaryotes examined. Phosphorylation can alter protein activity or subcellular localization, target proteins for degradation and effect dynamic changes in protein complexes. In many cases, different kinases may be involved in each of these processes for a single protein, allowing a large degree of combinatorial regulation at the post-translational level. Therefore, knowing which kinases are activated during a response and which proteins are substrates is integral to understanding the mechanistic regulation of a wide range of biological processes. In this paper, I will describe methods for monitoring kinase activity, investigating kinase-substrate specificity, examining phosphorylation in planta and the determination of phosphorylation sites in a protein. In addition, strategic considerations for experimental design and variables will be discussed.     

Phosphoproteome profiling for cold temperature perception

Temperature sensation initiates from the activation of cellular receptors when the cell is exposed to a decrease in temperature. Here, we applied a phosphoproteome profiling approach to the human lung epithelial cell line BEAS‐2B to elucidate cellular cold‐responsive processes. The primary aim of this study was to determine which intracellular changes of phosphorylation are accompanied by cold sensation. Eighteen protein spots that exhibited differentially phosphorylated changes in cells were identified. Most of the proteins that were phosphorylated after 5 or 10 min were returned to control levels after 30 or 60 min. Identified proteins were mainly RNA‐related (i.e., they were involved in RNA binding and splicing). Temperature (18 and 10°C) stimuli showed homologies that were detected for time course changes in phosphoproteome. The data indicated a time‐shift between two temperatures. The phosphorylation of putative cold responsive markers, such as ribosomal protein large P0 and heterochromatin‐associated proteins 1, were verified by Western blotting in cells transfected with TRPM8 or TRPA1. J. Cell. Biochem. 112: 633–642, 2011. © 2010 Wiley‐Liss, Inc.     

磷酸化蛋白质组学的新进展及其在肝脏生理和病理机制中的应用

蛋白质磷酸化是最常见的蛋白质翻译后修饰形式。由于蛋白质的磷酸化形式可以被磷酸酶和磷酸激酶进行可逆的调控,所以在众多的生命活动过程中蛋白质的磷酸化修饰起着重要的调控作用,因此对生物体内蛋白质磷酸化修饰的系统研究对于揭示生命科学的奥秘显得十分重要。近年来,随着质谱技术和生物信息学软件以及磷酸化肽段富集方法的发展,利用质谱对生物体内蛋白质磷酸化修饰研究的技术逐渐成熟。肝脏作为人体最重要的代谢和免疫器官,深入研究肝脏细胞内蛋白质磷酸化修饰形式对于理解其功能具有重要指导意义。目前,迅速发展的磷酸化蛋白质组学技术已经被广泛应用到肝脏功能的生物学研究中。这些研究加深了人们对肝脏的生理及病理状态的分子生物学机制的了解。本文综述了当前磷酸化蛋白质组学的研究进展和磷酸化蛋白质组学在肝脏中的研究。     

Global analysis of phosphoproteome dynamics in embryonic development of zebrafish (Danio rerio)

The zebrafish (Danio rerio) is a popular animal model used for studies on vertebrate development and organogenesis. Recent research has shown a similarity of approximately 70% between the human and zebrafish genomes and about 84% of human disease‐causing genes have common ancestry with that of the zebrafish genes. Zebrafish embryos have a number of desirable features, including transparency, a large size, and rapid embryogenesis. Protein phosphorylation is a well‐known PTM, which can carry out various biological functions. Recent MS developments have enabled the study of global phosphorylation patterns by using MS‐based proteomics coupled with titanium dioxide phosphopeptide enrichment. In the present study, we identified 3500 nonredundant phosphorylation sites on 2166 phosphoproteins and quantified 1564 phosphoproteins in developing embryos of zebrafish. The distribution of Ser/Thr/Tyr phosphorylation sites in zebrafish embryos was found to be 88.9, 10.2, and 0.9%, respectively. A potential kinase motif was predicted using Motif‐X analysis, for 80% of the identified phosphorylation sites, with the proline‐directed motif appearing most frequently, and 35 phosphorylation sites having the pSF motif. In addition, we created six phosphoprotein clusters based on their dynamic pattern during the development of zebrafish embryos. Here, we report the largest dataset of phosphoproteins in zebrafish embryos and our results can be used for further studies on phosphorylation sites or phosphoprotein dynamics in zebrafish embryos.